Stephanie S. Porter scite author profile

Plants are rife with bacteria and fungi that colonize roots and shoots both externally and internally. By providing novel nutritional and defense pathways and influencing plant biochemical pathways, microbes can fundamentally alter plant phenotypes. Here we review the widespread nature of microbially mediated plant functional traits. We highlight that there is likely fitness conflict between hosts and symbionts and that fitness outcomes can depend on partner genotypes and ecological factors. Microbes may influence ecosystems through their effects on the functional trait values and population dynamics of their plant hosts. These effects may feed back on symbiont evolution by altering transmission rates of symbionts and scale up to ecosystem processes and services. We end by proposing new avenues of research in this emerging field.

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Cheaters must prosper: reconciling theoretical and empirical perspectives on cheating in mutualism

Jones

et al. 2015

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Cheating is a focal concept in the study of mutualism, with the majority of researchers considering cheating to be both prevalent and highly damaging. However, current definitions of cheating do not reliably capture the evolutionary threat that has been a central motivation for the study of cheating. We describe the development of the cheating concept and distill a relative-fitness-based definition of cheating that encapsulates the evolutionary threat posed by cheating, i.e. that cheaters will spread and erode the benefits of mutualism. We then describe experiments required to conclude that cheating is occurring and to quantify fitness conflict more generally. Next, we discuss how our definition and methods can generate comparability and integration of theory and experiments, which are currently divided by their respective prioritisations of fitness consequences and traits. To evaluate the current empirical evidence for cheating, we review the literature on several of the best-studied mutualisms. We find that although there are numerous observations of low-quality partners, there is currently very little support from fitness data that any of these meet our criteria to be considered cheaters. Finally, we highlight future directions for research on conflict in mutualisms, including novel research avenues opened by a relative-fitness-based definition of cheating.

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Selection for cheating across disparate environments in the legume‐rhizobium mutualism

Porter

Simms

2014

Ecology Letters

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The primary dilemma in evolutionarily stable mutualisms is that natural selection for cheating could overwhelm selection for cooperation. Cheating need not entail parasitism; selection favours cheating as a quantitative trait whenever less-cooperative partners are more fit than more-cooperative partners. Mutualisms might be stabilised by mechanisms that direct benefits to more-cooperative individuals, which counter selection for cheating; however, empirical evidence that natural selection favours cheating in mutualisms is sparse. We measured selection on cheating in single-partner pairings of wild legume and rhizobium lineages, which prevented legume choice. Across contrasting environments, selection consistently favoured cheating by rhizobia, but did not favour legumes that provided less benefit to rhizobium partners. This is the first simultaneous measurement of selection on cheating across both host and symbiont lineages from a natural population. We empirically confirm selection for cheating as a source of antagonistic coevolutionary pressure in mutualism and a biological dilemma for models of cooperation.

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Agriculture and the Disruption of Plant–Microbial Symbiosis

Porter

Sachs

2020

Trends in Ecology & Evolution

113

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Domestication has transformed hundreds of wild plant species into productive cultivars for human utility. However, cultivation practices and intense artificial selection for yield may entail a hidden cost: the disruption of interactions between plants and beneficial microbiota. Here, we synthesize theory predicting that evolutionary trade-offs, genetic costs, and relaxed selection disrupt plant-microbial symbiosis under domestication, and review the wealth of new data interrogating these predictions in crops. We describe the agronomic practices, ecological scenarios, and genomic attributes that can result in the disruption of symbiosis, and highlight new work probing its molecular basis. To improve agricultural output and sustainability, research should develop breeding methods to optimize symbiotic outcomes in crop species. The Disruption of Symbioses in Domesticated Plants Humans have reshaped the biosphere, driving rapid evolution in the species that we exploit [1]. Agriculture stands out as a vast human alteration of biodiversity on Earth: over 12 000 years, humans have molded hundreds of wild plant species into productive crops [2] that cover N35% of the terrestrial habitat [3]. Domestication is a multistaged response to human-imposed selection that progresses from the increase in frequency of desirable alleles in nearly wild populations, to the formation of cultivated populations and deliberate breeding and improvement [4]. Breeding practices have favored crop lineages that produce large, flavorful, and rapidly growing vegetative structures, fruits, and seeds, with improved disease resistance and environmental tolerance traits that manifest primarily in aboveground plant tissues [2]. However, belowground traits can be difficult for humans to evaluate during domestication and crop improvement [5]. Thus, the evolutionary disruption of plant-microbe symbioses (see Glossary), that is, a decrease in the interaction of crops with beneficial soil microbiota [6-8], can go undetected. Highlights Many crops interact differently with beneficial microbiota compared with their wild relatives.

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Beneficial microbes ameliorate abiotic and biotic sources of stress on plants

et al. 2020

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